Optical tracking with two markers for robust prospective motion correction for brain imaging

Singh, Aditya; Zahneisen, Benjamin; Keating, Brian; Herbst, M.; Chang, Linda; Zaitsev, Maxim; Ernst, Thomas

doi:10.1007/s10334-015-0493-4

Cited by 24 publications

(29 citation statements)

References 24 publications

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“…However, instabilities due to incorrect motion correction have also been reported [12], [13]. The combination of external tracking data with image-based navigator information can help overcome this problem.…”

Section: Discussionmentioning

confidence: 99%

“…Integrating optical and image based motion correction effectively removed errors related to slippage of the optical marker, which is one of the challenges for external motion tracking [12], [13]. Furthermore, motion-induced inconsistencies in coil sensitivity profiles resulted in small but noticeable errors in SMS reconstruction of phantom data.…”

Section: Discussionmentioning

confidence: 99%

“…Motion correction with external optical tracking can improve DWI data quality [8]–[11]. However, affixation of tracking markers can be challenging and marker “slippage” during the scan will compromise the quality of motion correction or even introduce artifacts [12], [13]. …”

Section: Introductionmentioning

confidence: 99%

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Motion correction for diffusion weighted SMS imaging

Herbst

Poser

Singh

et al. 2017

Magnetic Resonance Imaging

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Motion correction for diffusion weighted SMS imaging

Herbst

Poser

Singh

et al. 2017

Magnetic Resonance Imaging

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“…The large gaps between coil rungs in the 8-channel head coil used in this study helps to maintain the line-of-sight that is required for optical tracking to work. However, even for coils with large gaps between coil rungs, a standard optical marker can be obstructed or partly leave the camera field-of-view [28]. Reasons for this include changes in initial marker placement and/or patient positioning, patient drifting during scan, or patient head being large such that the marker is very close to the camera.…”

Section: Discussionmentioning

confidence: 99%

Prospective motion correction for 3D pseudo-continuous arterial spin labeling using an external optical tracking system

Aksoy

Maclaren

Bammer

2017

Magnetic Resonance Imaging

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Head motion is an unsolved problem in magnetic resonance imaging (MRI) studies of the brain. Real-time tracking using a camera has recently been proposed as a way to prevent head motion artifacts. As compared to navigator-based approaches that use MRI data to detect and correct motion, optical motion correction works independently of the MRI scanner, thus providing low-latency real-time motion updates without requiring any modifications to the pulse sequence. The purpose of this study was two-fold: 1) to demonstrate that prospective optical motion correction using an optical camera mitigates artifacts from head motion in three dimensional pseudo-continuous arterial spin labeling (3D PCASL) acquisitions and 2) to assess the effect of latency differences between real-time optical motion tracking and navigator-style approach (such as PROMO). An optical motion correction system comprising a single camera and a marker attached to the patient’s forehead was used to track motion at a rate of 60fps. In the presence of motion, continuous tracking data from the optical system was used to update the scan plane in real-time during the 3D-PCASL acquisition. Navigator-style correction was simulated using the tracking data from the optical system, but updates were performed only once per repetition time. Three normal volunteers and a patient were instructed to perform continuous and discrete head motion throughout the scan. Optical motion correction yielded superior image quality compared to uncorrected images or images using navigator-style correction. The standard deviations of pixel-wise CBF differences between reference and non-corrected, navigator-style-corrected and optical-corrected data were 14.28, 14.35 and 11.09 mL/100g/min for continuous motion, and 12.42, 12.04 and 9.60 mL/100g/min for discrete motion. Data obtained from the patient revealed that motion can obscure pathology and that application of optical prospective correction can successfully reveal the underlying pathology in the presence of head motion.

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“…With optical tracking the range of trackable motion can be limited by line-of-sight requirements. A redundant multi-camera or multi-marker approach can increase the possible range of motion (Singh et al 2015). …”

Section: Motion Detection Techniquesmentioning

confidence: 99%

Motion correction in MRI of the brain

et al. 2016

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Subject motion in MRI is a relevant problem in the daily clinical routine as well as in scientific studies. Since the beginning of clinical use of MRI, many research groups have developed methods to suppress or correct motion artefacts. This review focuses on rigid body motion correction of head and brain MRI and its application in diagnosis and research. It explains the sources and types of motion and related artefacts, classifies and describes existing techniques for motion detection, compensation and correction and lists established and experimental approaches. Retrospective motion correction modifies the MR image data during the reconstruction, while prospective motion correction performs an adaptive update of the data acquisition. Differences, benefits and drawbacks of different motion correction methods are discussed.

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Optical tracking with two markers for robust prospective motion correction for brain imaging

Cited by 24 publications

References 24 publications

Motion correction for diffusion weighted SMS imaging

Motion correction for diffusion weighted SMS imaging

Prospective motion correction for 3D pseudo-continuous arterial spin labeling using an external optical tracking system

Motion correction in MRI of the brain

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